CS205104B2 - Oxygen,event.air diffusing electrode for the electrochemical current sources of the type metal-oxygen event. metal for the rolling cells - Google Patents

Description

The invention relates to an oxygen or air diffusion electrode for metal-oxygen or metal-air electrochemical current sources and for fuel cells.

For general theoretical reasons, the oxygen or air diffusion electrodes must meet a variety of contradictory requirements, such as having a large internal catalytic surface and being readily accessible to oxygen. Likewise, there must be no leakage of the electrolyte, while at the same time some of the electrode pores are filled with electrolyte; The three-phase interface area of the gas (electrode) electrolyte must be large in size and the electrode must have low ohmic resistance. In practice, high current density, long life, low weight and small dimensions are also required. The materials used must be inexpensive and easy to reach.

Gas diffusion electrodes are known which meet only some of the requirements. Many of these electrodes use platinum, silver or other noble metal as a catalyst, which is mixed with a polytetrafluoroethylene emulsion, applied to a metal mesh and sintered (U.S. Pat. No. 3,410,935). In other types of oxygen electrodes, platinum black is used as the catalyst (British Pat. No. 1,163,479). Catalysts 2 of other electrodes consist of a combination of precious metal and activated carbon (U.S. Pat. Nos. 3,425,875, 3,423,247, Swiss Patent No. 477,098, Japanese Patent No. 17,686, and German Patent No. 56 837). Existing oxygen electrodes also exist where the catalyst is mixed with a hydrophobicizing agent and the homogeneous hydrophobicized layers are deposited on a strongly hydrophobicized carbonyl, nickel backing (U.S. Pat. No. 3,540,010). This increases the degree of hydrophobization of the layers; in the direction of the washer.

A common drawback of the above-described gas and oxygen diffusion electrodes is that improving certain properties leads to deterioration of other important properties of the electrodes. With electrodes with hydrophobic catalyst layers, it is particularly difficult to achieve a high current density and a long service life at the same time. This is especially true for non-positive pressure oxygen oxygen electrodes.

Only electrodes with the addition of platinum as a catalyst have relatively better electrochemical properties, but they cannot be used in practice due to the high cost of platinum.

The purpose of the present invention is to overcome these drawbacks and to provide an oxygen or air diffusion electrode without expensive precious metal catalysts, which nevertheless has high electrochemical and electrical values when used in electrochemical power sources.

The object of the invention is an oxygen or air diffusion electrode, which consists of an electrically conductive porous catalytic layer and an electrically conductive porous hydrophobic gas-permeable layer, which are pressed onto a metal mesh. SUMMARY OF THE INVENTION The catalytic layer consists of interpenetrating porous hydrophilic regions having catalytic activity for electrochemical oxygen reduction and porous hydrophobic regions of conductive hydrophobized pore-free grains, wherein the dimensions of the hydrophilic interpenetrating hydrophilic intersections throughout the catalytic layer are porous hydrophobic regions. and the dimensions of the hydrophobic areas decrease. The hydrophobic regions are preferably of carbon black, which are hydrophobized with polytetrafluoroethylene and / or polyisobutylene and / or polyethylene and / or polypropylene, while the hydrophilic regions are of a hydrophilic catalytically active material whose grains exhibit a strongly developed microporous structure, for example activated carbon or other. a porous catalyst; the ratio of hydrophobized carbon black to non-hydrophobized activated carbon in the catalyst layer is in the range of 1: 5 to 5: 1 parts by weight.

The electrode according to the invention has electrochemical properties comparable to those of electrodes which contain platinum catalysts and are therefore substantially more expensive than activated carbon electrodes.

An exemplary embodiment of an oxygen or air electrode according to the invention is shown in the drawing, wherein FIG. 1 is a cross-section of a cut-out of the electrode, and FIG.

The electrode consists of an electrically conductive porous catalytic layer 4 and an electrically conductive porous hydrophobized gas permeable layer 5. An imaginary interface is indicated between the two layers 4, 5 by a broken line. The electrode further comprises a metal grid (not shown) located on or within one surface of the electrode or within its body. The gas-permeable layer 5 is supplied with gas in the direction of arrow 7 and to the catalytic layer 4 with an electrolyte in the direction of arrow 8.

The catalytic layer 4 is comprised of a plurality of electrically conductive porous hydrophilic regions 2, such as activated carbon, and a plurality of electrically conductive porous hydrophobic regions 1. The hydrophobic regions 1 may consist, for example, of a large number of hydrophobized pore-free grains such as carbon black hydrophobized polytetrafluoroethylene. The hydrophilic regions 2 contact the hydrophobic regions 1 at the interface 3.

The gas-permeable layer 5 also consists of pore-free hydrophobized grains 6, for example of carbon black hydrophobized with a polymer such as polytetrafluoroethylene, polyisobutylene, polyethylene or polypropylene, and may contain up to 50 wt. polymer.

The hydrophobic regions 1 and the hydrophilic regions 2 cross each other, as shown in FIG. 2, drawn on an enlarged scale. However, the representation of the layers and areas in the drawing is only schematic and does not show their exact shape or structure, which are variable. Also, the number of intersecting areas is in fact substantially greater than in the drawing.

The hydrophobic regions 1 and hydrophilic regions 2 extend over the entire thickness of the catalytic layer, as shown by their height Ai, Az in Figure 2. Towards that electrode surface that touches the electrolyte, i.e. in the direction of the arrow Z, the cross-section B2 of the hydrobobic regions 1 decreases while the cross-section Bi of the hydrophilic regions 2 increases in this direction. Thus, the ratio between the hydrophobic regions 1 and the hydrophilic regions 2 varies in the direction of the arrow Z, the volume of the hydrophobic regions 1 decreasing in this direction and the volume of the hydrophilic regions 2 increasing. Thus, only the transverse dimensions of the regions 1, 2 vary in the thickness of the catalytic layer 4, but not their physical and electrochemical properties.

The catalyst layer 4 is applied in several layers, each having a different ratio of hydrophobized carbon black to non-hydrophobized activated carbon, for example from 1: 5 to 5: 1 parts by weight. The electrode is then sintered at a temperature of 150 to 350 ° C and a pressure of up to 30 MPa.

The described structure of the oxygen or air electrode according to the invention leads to a substantial improvement in its chemical properties. The reaction interface of the three phases occurring in the catalytic layer 4 in the three-dimensional volume increases the overall efficiency of the electrode. The structure of the catalytic layer complies with the countercurrent principle, which ensures an optimal distribution of the working process in the electrode. Due to the sharp transition of the hydrophilic regions 2 and hydrophobic regions 1, the position of the three-phase interface in which the electrochemical process takes place does not change during operation of the electrode. According to the invention, this ensures an extremely long service life of the oxygen or air electrodes, namely 10,000 and 15,000 hours at stable, high electrochemical analytical values. In this case, no current passage has been detected in the electrodes, which is of great importance for their use in practice and can be described as a further advantage. These facts are confirmed by the results of analytical tests of oxygen and / or air electrodes, which are summarized in Table 1.

The oxygen or air electrodes according to the invention are universally applicable. They are used successfully in electrochemical metal-air current sources, both as primary batteries and as secondary accumulators, as well as in various types of fuel cells. The electrodes can also be used in devices for determining minimum amounts of oxygen and in devices for extracting pure oxygen from the air.

TABLE 1

Life and electrochemical initial analytical values of oxygen or air diffusion electrodes according to the invention made with various hydrophobic substances catalyst hydrophobic working gas Current density flow density h substance and binder without overpressure at polarization du at long - 200 mV against good Hg / HgO, mA tests. cm ^-2 mA. cm ^-2

activated carbon polytetrafluor- air 150 30 15 000 ethylene 50 10 000 100 ALIGN! 1 000 oxygen 300 100 ALIGN! 5 000 200 4 000 activated carbon polyisobutylene air 150 50 4 000 oxygen 300 -  - activated carbon polyethylene air 150 50 2 000 oxygen 250 - -

SUBJECT OF THE INVENTION

Claims (4)

1. Oxygen or air diffusion electrode for metal-oxygen or metal-air electrochemical current sources and for fuel cells consisting of an electrically conductive porous catalytic layer and an electrically conductive porous hydrophobic gas-permeable layer, which are pressed onto a metal mesh, characterized in that the catalytic layer (4) is formed by interconnecting porous hydrophilic regions (2) with catalytic activity for electrochemical oxygen reduction and porous hydrophobic regions (1j) from conductive hydrophobized grains free of pores, wherein in the direction of gas passage the whole catalytic The dimensions of the interconnecting hydrophilic regions (2) increase and the dimensions of the hydrophobic regions (1) decrease. Oxygen or air diffusion electrode according to claim 1, characterized in that the hydrophobic regions (1j) are of carbon black, which are hydrophobized with polytetrafluoroethylene and / or polyisobutylene and / or polyethylene and / or polypropylene. Oxygen or air diffusion electrode according to rolls 1 and 2, characterized in that the hydrophilic regions (2) are of hydrophilic catalytically active material whose grains have a strongly developed microporous structure, for example activated carbon or other porous catalyst. Oxygen or air diffusion electrode according to Claims 1 to 3, characterized in that the ratio of hydrophobized carbon black to non-hydrophobized activated carbon in the catalytic layer (4j) ranges from 1: 3 to 5: 1 parts by weight. 1 sheet of drawings